US2995696A - Alternating current generating system - Google Patents

Description

Aug. 8, 1961 1.. J. STRATTON E AL 2,995,695

' ALTERNATING CURRENT-GENERATING SYSTEM 7 Sheets-Sheet 3 "1 v f 3/ w med on. e, 1958 REcTI FICATION luvsnsm POSITIVE P$ITIVE INVVERSION GROUP cpoup NEGATIVE cno'up v QECTIFICATION NEGATIVE aaoup INVENTORS Aug. 8, 1961 L. J. STRATTON ETAL' 2,995,696

ALTERNATING CURRENTGENERATING SYSTEM Filed Oct. 6', 1958 7 Sheets-Sheet 4 STATlC FREQUENCY CHANGER Excrrimou Com-EDI.

PULSE CONSTANT 1/ FREQUENCY l SOURCE INVENTOR v KEITH M (u/eqww ,8

LA WEE/VCE J 572,4 710w 1 8- 1961 L. J. STRATTON ETAL 2,995,696

ALTERNATING CURRENT GENERATING SYSTEM Filed Oct. 6, 1958 7 Sheets-Sheets INVENTORS KE/ TH M. C'H/EG WIN Y LA WEENCE' J 57794 Tm/v ,QTTOENE Y5 u 8, 1 L. J. STRATTON ETAL 2,995,696

' ALTERNATING CURRENT GENERATING SYSTEM PiledOct. e, 1958 7 Sheets-Sheet 6 mm 4 W 6 M Armeme Y5 Filed Oct. 6, 1958 m. H. V

AME-- L. J. STRATTON ET AL ALTERNATING CURRENT GENERATING SYSTEM '7 Sheets-Sheet 7 INVENTOR} KEITH M. CH/eqw/N g BY Lamas/v05 J STPATTUA/ ATToeA/E Y5 United States Patent O ALTERNATING CURRENT GENERATING SYSTEM Lawrcnce J. Stratton, Lyndhurst, and Keith M. Chirgwin,

Redford Heights, Ohio, assignors, by mesne assignments, to The Siegler Corporation,-Los Angeles, Calif a corporation of Delaware, FiledOct. 6, 1958. Ser. No. 765,472

25 Claims. (Cl. 3 22-'-32) put of an induction generator can be controlled either by controlling the speed of the shaft driving the generator or by controlling the frequency and phase relationship of the exciting windings, of the generator. At-the present time in A.C." systems for aircraft'and missiles, aconstant' speed drive mechanism is employed in conjunction with a synchronous alternator. This is unsatisfactory because of the weight arid cost of the constant speed drive and the difficulty of maintenance. Furthermore, constant speed drives do not respond rapidly enough to hold the outputfrequency of the machine within the tolerances that are often required. It has been proposed to control the excitation of asynchronous generators to produce outputs of substantially constant frequency, but the previous systems have not=bcen adapted for services such as aircraft or missiles'becauscof defects such as "insuiiicient speed range that can be toleratedin the prime mover, the

. requirement of a large synchronous A.C. system into which the asynchronous generator output can be tied. the

. '2 speed, even though the rotor is not rotating at synchronous speed. Whenever the field rotates at synchronous speed, the generatoroutput will be of the desired frequency. When the rotor is operatcd at speeds below synchronous speed, the rotor-field rotates with respect to the rotor in a direction such that its speed of rotation is added to the rotor speed to bring the speed of the field up to symchronous speed. Conversely, when the rotor is operated above synchronous speed, the excitation of the rotor is such that the rotor field rotates with respect to the rotor in a direction so that the speed of rotation of the field is subtracted from the speed of rotation of the rotor to bring the speed of the field down to synchronous speed.- Those skilled in the art will recognize that the apparatus can be made with the exciting windings on the.

stator and the output windings on the rotor, in which case the field is made to rotate with respect to the stator at slip frequency so that the relative rotation between the -rotor (which carries the output windings) andthe field'will'be at synchronous speed. This type of machine is less'desir'able, however, because the output must be throughslip rings.

necessity of using commutator machines that are required to handle power, and other like difficulties.

A general object of the present invention, therefore. is the provision of a variable speed constant frequency generating system in which the difiicultics with prior systems are eliminated and which is particularly adapted to severe service requirements such as are encountered in aircraft and missiles. Another object is the provision of such a system in which itis not necessary to tie the generator 'into an existing constant frequency systemQwhich does not require a commutator machinc'for the handling of any substantial amount of power and which will operate with efficiency of a. reasonably high order above, below and at synchronous speed.

In machinesof the induction type, if the excited windings, which are ordinarily the rotor windings, are excited .with D.C.,' the desired output frequency is produced at one particular shaft speed. Thisis referred to herein as synchronous speed. For'example', in a four pole aircraft generator. with an output frequency of 400 cycles, synchronous speed is 12,000 rpm. The output frequency of the machine with DC. excitation is hereinafter referred to as "shaft frequency." Shaft frequency is equal to the desired output frequency when the shaft is driven at synchronous speed;

At's'ynchron'ous' speed with DC. excitation, the field rotates at the same speed as the rotor; i.e., the field and the rotor both rotate at synchronous speed and the field is stationary with respect to the exciting windings. If,

I however, the excitation is by polyphase alternating current, the'field can be made to rotate with respect to the excitingwindings carried by the rotor so that the field will rotate with respect to the stator at a speed either The direction of rotation of the field which is required when the rotor isdriven below synchronous speed is called positive hereinafter, and the direction required when the rotor is driven above synchronous speed is called negative" hereinafter. The frequency required to produce the desired, rotation of the field with respect to the rotor islequal to the difference between shaft frequency and the desired outputfrequency and is hcreinafter called "slip frequency. When the rotor is operatit'tg precisely at synchronous speed, the slip frequency is zero and the excitation is direct current; the'term slip frequency" as used herein includes this condition. When positive rotation of the rotor field is required. and also at synchronous speed of the rotor, excitation power must be-supplicd to the rotor from some external source. When negative rotation of the rotor field is required, power is generated in the rotor windings and must be absorbed externally of the rotor. The basic principles are all weltknown'. The present invention provides a practical system utilizing the basic principles to produce a reliable generating system that can be employed to provide alternating current of closely regulated frequency with reasonable elliciency of operation of the machine machine.

Preferred forms of the invention are shown in the drawings in which:

FIGURE 1 diagrammatically illustrates one preferred form of generating system embodying our invention.

FIGURE 2.is a wiring diagram illustrating a preferred form of static frequency changer and a preferred form of pulse generator for use in the' system shown in FIG- URE l.

"FIGURES 3, 4, SA and 5B are diagrams illustrating the operation of the static frequency changerand pulse generator of FIGURE 2.

FIGURE 6 diagrammatically illustrates another preferred form of system embodying the invention.

FIGURE 7 is a wiring diagram illustarting a preferred form of static frequency changer and 'a preferred form of pulse generator 'for use in the system shown in FIG- URE 6, and

' FIGURES 8A. 88, 9A, 98, 10A and 10B are diagrams illustrating the operation of the static frequency changer and pulse generator of FIGURE 7.

A generating system made according to one preferred form of the invention is shown in FIGURE 1 of the drawings. As indicated in that figure, all of therotating components of the machine are mounted on a shaft S which is arranged to be driven at variable speeds by a prime Patented Aug. 8, 1961 mover not shown,

The system is designed to supply three phasealternating current of substantially constant frequency to the bus bars regardless of rather wide variations in the speed of the shaft S. For example, the system may be designed to'generate400cyclc A.C. within a frequency tolerance of cycle per second throughout a shaft speed range of 6,000 r.p .rn. to 15,000 r.p.'m., with synchronous speed being l2,000 r .p.m.

The mam rotating machine of the system is an induction generator indicated in general at 11 This is a nonsalient pole machine shown as having three phase rotating exciting windings 12 and three phase stationary output windings 14 that are connected to the buses 10. If desired, a synchronous condenser 15 may be connected to the buses 10 to balance the voltages between the phases when the load is unbalanced, to smooth out the output wave, to improve the power factor of the induction generator 11 and to provide excitation there'fon I The exciting windings 12 of the rotor are supplied through slip rings with slip frequency excitation current by means of a static frequency changer 17, which is described below. Depending upon the system requirements, the excitation current may be A.C. of such phase relation ship that positive rotationof the field is produced, may be D.C., or maybe A.C. of such phase relationship that negative rotation of the rotor field is produced, in which case the flow of poweris from the rotor windings through the' slip' rings 'tothe static frequency changern The-three phases of the-slip frequency supply are designated a, b and c in the drawings. The, static frequency changer is supplied'by a synchronous exciter indicated .in general at 18 and'having 'a'rotor 20 and stator 21. This machine acts as a generator ora motor, deperiding on the direction of transferof power and is preferably designed to'operateat a frequency thatfis two to three times'the highest slip frequency that is -required by the exciting windings 12 to maintain the output frequency .of the main generator constant within the'designed speed range. The output frequency of the exciter is hereinafter referredjto as the high' frequency supply because of the requirement that it be hi'gh' with respect to the slip frequency. Actually, the high frequency may be equal. to shaft frequency,'but in this form of the invention it is preferably two or three times shaft frequency in order to give a widerrangc of operating speeds with reasonably good wave form. The three'phases' of the high frequency supply are designated a, b and c-'.' Excitation for the rotor 20 of the synchronous exciter 18 is supplied by a permanent magnet generator 22 through a static rectifier and excitation control shown zit-.23. Control 23 maybe of any conventional type, including, for exa1nple,'silicon.or selenium rectifiers and other appropriate components to control the excitation of the exciter 18, and will not be described furtherhe'rein. The static frequency changer 17 is cont-rolled to provide the proper slip frequency excitation of the rotor 12 by meansof 'a pulse generator 25 which is described indetail below. 'Pulse generator 25 receives slip frequency signals from a commutator frequency changer 27. This machine derives the slip frequency signal current from a constant frequency source having an output frequency equal to the desired outputfrequency of the main generator and may be of a well-known type. It is supplied with A.C. of. the desired output frequency (in this'instance, 400 cycles) from ac'onstant reference frequency source 28, which may be of any conventionalconstruction such as a tuning fork controlled oscillator or generator, through the slip rings 29 to the rotor winding 30. The rotor winding is connected at many points to the segments of commutator -31, the connections being omitted for convenience in the drawing. There is no stator winding in this type of machine; the rotor has thesame number of poles as the main induction generator 11. The rotation of the commutator at the variable shaft speed resultsin the production of a slip frequency signal. Inasmuchas this is simply a control signal, the machine has substantially no power output and the problems of commutation are of no great consequence. The three phases of the slip frequcucy signal are designated a", I)" and c".

The slip frequency signal produced by the slip frequency generator 27 and the high frequency output of the synchronousexciter 18 are utilized in the pulse generator 25 to produce signal pulses that control the static frequency changer 17 to cause it to convert the high frequency supply to slip frequency current of the .proper phase and frequency to supply the rotor winding 12 with the excitation required to produce the required constant frequency output in the stator 14 of the main generator 11. Again, it is to be noted that at synchronous speed the output of the static frequency changer is D.C. At speeds below synchronous, power is supplied by the exciter 18 and static frequency changer 17 to the rotor 12.

At speeds above synchronous speed, power is supplied into the shaft S; the exciter 18 operates as a synchronous motor under these conditions.

Successful operation of the system depends on the static frequency changer 17 and the pulse generatorZS. Circuit diagrams of these devices are shown in FIGURE 2. The static frequency changer 17 is shown in the right hand portion of FIGURE 2 and preferably is of the cycloconverter" type.-' Cycloconverters have the ability to convert electric power of one frequency to power of another frequency with the flow of energy taking place in either direction as required. This is accomplished by means of electronic switching devices. In the past, the switching devices have ordinarily consisted of thyratrons ignitrons, mercury arc rectifiers and the like. While the circuits of the cycloconv'erter preferably employed in the present application are of the same general character as the prior art, solid state devices are preferably used as the electronic switching devices. These solid state devices may be transistors coupled with rectifiers but preferably are controlled rectifiers. These are current-controlled electronic switching and rectifying devices.

As shown in FIGURE 2, the static frequency changer 17 is made up of asmany sections as there are phases of the slip frequency supply. In the present embodiment there are three sections 17a, 17b and 17c, for phases a, b and c, respectively, of the slip" frequency supply. The sections are identical in all material respects; for this reason only section 17a is described and shown in detail herein. Section 17a preferably comprises six substantially identical controlled silicon rectifiers 38; the individual rcctifiers are"identified by numerals 1, 2, v 3, 4, 5 and 6. The rectifiers are connected in pairs, one pair for each phase of the high frequency supply, with the rectifiers in each pair connected back to back; i.e., ar' ranged for conduction in opposite directions. Rectifiers 1 and 2 are connected to phase a, rectifiers 3 and 4 are connected to phase b', and rectifiers 5 and 6 are connected to the phase c' of the high frequency line to the stator 21 of exciter 18. The. even numbered rectifiers are referred to hereinafter as positive rectifiers because they conduct when the slip frequency current is positive while, conversely, the odd numbered rectifiers arereferred to as negative rectifiers. The negative rectifiers 1, 3 and 5 are connected to conductor 39 and through a choice to phase a of the slip frequency supply leads to the rotating field 12 of generator 11. The positive rectifiers 2, 4 and 6 are connected to line 41 and through choke 42 to the same phase. Chokes 40and' 42 are shown as separate elements, but in effect'they constitute a center tapped choke. conductors 45 in the positive rectifier lead extend to the pulse generator 25. The connections to the pulse generator are series connections which are explained below.

In the arrangement shown, there are six controlled rectifiers for each of the three phases of the generator slip Conductors 44 in the negative rectifier lead and form that is produced.

' generator.

frequency supply. It is, therefore, a half wave device; the chokes 40 and 42 smooth the somewhat jagged wave 1t isevident that a full wave device embodying thirty-six controlled rectifiers or other electronic switching devices could be employed with a three phase generator and a three phase excite'r and that other numbcrsotcontrolled switching devices will be appropriate to generators and exciters having different numbers of phases. For example, it may be desirable to utilize 6 or .12 phase excitersto obtain better wave forms in the slip frequency. Also, as power is increased, further division of the power requirements between a greater number of controlled rectifiers may be desirable. Mod ifications of this sort are contemplated by the present in vention. l

The controlled silicon rectifiers are PNPN semi-con-v ductors each having an anode 46, a cathode 47 and a gate 48. The rectifiers are. normally non-conducting. Avalanche breakdown of the center junction is achieved by applying a signal to 'the gate, a very briefcurrent pulse of i milliamperes at 1 volts gate-to-cathode being sufiicent. Theamplitude of the current pulses is not critical, so long as it is sufiicient to fire the rectifiers. Breakdown occurs at speeds-that are almost instantaneous; after breakdown the-voltage across the rectifiersis very low. An extremely small amount of power-applied at the gate makes it possible to control the switching action of the rectifiers at a very high rate of speed. When a rectifier is fired by applying appropriate current to the gate. Ihb'ICClifiCl' becomes c'onductive and continues. to conduct until the forward voltage is removed; in this respect the device acts much in the manner of a thyratron.'- it can be made conductive during'any part of the positive half cycle'of the anode to cathode voltage and will remain conductivethroughout the remainder of the positive half cycle or'until it is turnedotf by the firing of another rectifier in the frequency changer. Thus, by applying appropriate signal currents at the correct times to the gates 48 of each-of the controlled rectifiers, the static'frequency changer can be caused to convert the high frequency current supplied by the exciter to the slip frequency current rcquired by'the generator with transfer of powerin either direction and at any power factor.

The required signal currents are supplied in the form of pulses by the pulse generator 25. The pulse generator is composed of three sections, 25a, 25b and 250 associated with sections 17a, 17b, and 170, respectively, of the frequency changer. Only section 2511 is illustrated in detail inasmnch'as the othersections are substantially identicaL' According to the present invention signal pulses are supplied to the gates 48 of the several controlled rectifiers at the correct instants required by the demands of the apparatus by means of magnetic core devices 1, 2, 3', 4', 5? and 6' which control the firing of rectifiers 1, 2, 3, 4, 5 and 6. respectively. Each magnetic core device preferabl' takes the form of a saturable pulse transformer having a toroidal core of square loop material, and' the devices are arranged in pairs corresponding to the arrangement otthe pairs of rectifiers in the static frequency changer. The magnetic core devices are substantially identical. but receive input signals from difierent phases of the high-frequency supply and of the slip frequency The core devices 1' and 2' for controlling the rectifiers 1 and 2 are described in detail herein, and the same reference characters are applied to corresponding parts'ot cores 3 and 5, and 4f and 6', respectively.

Each core is-provided with five windings. On core 1 these are input windings 50, 51, S2 and S3 and output winding 54. On core 2, the input windings are indicated at 60. 61., 62 and 63 and thci output winding at 64. The devices are constructed so that the cores are in a state of either negative saturation or positive saturation except when the algebraic sum of'the ampere turns in the several pulse is generated in an output winding only when the associated corc goes from one state of saturation to the opposite state of saturation. if necessary, a rectifier 55 can be inserted in the output circuit from winding 54 and a rectifier 65 in the corresponding circuit from winding 64 to permit current to flow only when the cores go from negative saturation to positive saturation. This takes place very rapidly so that the firing of the controlled rectifiers by the resultant pulses can be accurately timed. The cores are saturated except for very brief intervals as they pass through zero, the amplitude of the firing pulses is not critical so long as sufficient current is supplied; therefore, accurate control of the firing time does 'not depend upon control of the degree of saturation of the cores and it is not necessary to match the cores or the windings with any great degree of accuracy. The output of winding 54 on core 1' is connected to the gatecathode circuit of rectifier 1 by conductors 56 and 57 as shown and the output of the winding 64 on core 2' is connected to the gate-cathode circuit of rectifier 2 by conductors 66 and 67 as shown. The outputs of the windings 54 on cores 3' and 5' are connected to the gateeathode circuits of rectifiers 3 and 5, respectively; theoutputs of the windings 64 on cores 4' and 6' are connected to the gale-cathode circuits of rectifiers 4 and 6, rcspcctively.

The instants at which rectifiers land 2 are fired are determined primarily by the inputs to thewindings and 51 of core I. and 60 and 61 of core 2'. windings 50 and 60 on all of the cores are connected in' series as shown and are connected between phase a" and ground or neutral n" of the slip frequency generator 27. A resistor 66 is incorporated in the circuit to provide a stable current source. windings 51 and 61 on cores l and 2 are also connected in series and are connected across phases a and c of the high frequency exciter 18. A choke 67 is incorporated in this circuit. This circuit provides a current through windings 5t and 61 that lags approximately 120 behind the voltage, of phase a which is supplied to rectifiers l and 2. The inductance 67 provides a lag. and the additional 30 is obtained by the connection across phases a and c as compared to the a to neutral voltage applied to the rectifiers 1 and 2. It would be possible to use another hightrequency I phase and eliminate the inductance, but the inductance is desirable in order to provide a constant current source and to minimize the effects of firing the cores on the high frequency supply circuit. Similar circuits are provided for connecting coils 5i and 61 on cores 3 and 4' across phases a and Ii of the high frequency supply and coils 51 and 61 on cores 5' and 6' across phases b and c of the high frequency supply. These circuits include inductances 68 and 69. respectively, and provide currents that lag phases b and 0. respectively by It is to be noted that the inputwindings on the even numbered cores and the input windings on the odd numbered cores are connected so that the cores in a pair fire apart.

windings 53 and 63 are provided on the cores to prevent any of the rcctifiers'ot one group from conducting at the same time that any of the rectifiers of the other group are conducting any substantial amount of current. When any rectifier in the positive group is conducting, the windings 53 on cores 1". 3' and 5'. which are all connected in series with the output of the positive rectifiers 2, 4 and 6 through conductors 45. are energized, saturating the cores and preventing the generation of'a signal pulse in the windings 54. Similarly, when any of the negative rectifiers 1.3 and 5 are conducting. the windings 63 on cores 2. 4 and 6 are energized through conductors 44. holding all of these cores in saturation and preventing firing of rectifiers 2. 4 and 6. it is to be noted that these signals are determined by the current flow.

input windings is substantially equal to zero. An output 75 This is important because in normal operation of the apparatus,.the output current and voltage are not in phase because of the reactive nature of the load.

' rents to the windings 52 7 phases b and c" of the windings 52 and 62 on cores 1', 3' and and cores 4' and 6, respectively, are connected across shunts 70 and 71 in the current feedback circuits 44 and 4 5, respectively. These windings slightly shift the zero axis of the cores and thereby shift the' firing points of the cores with which they are associated. For example, when the negative group of controlled rectifiers 1, 3 and 5 are conducting the current passed by the negative group develops voltage's across the shunts 70; this supplies curon' the cores 1, 2 and 3'. These additional ampere turns slightly advance the firing points of the cores in order to compensate for commutating overlap which varies, approximately directly with the current. The windings 62.0n cores 2', 4' and 6', connected across shunts 71, provide corresponding compensation for the positive group of controlled reetifiers. These windings do 'not appear to be essential to satisfactory operation, but are desirable.

. -;With this circuit, the three phase high frequency supply from the exciter is converted to phase a of the low or slip frequency supply to the generator field, in-response to phase a" of the slip frequency signal. Phases b and c of the slip frequency supply are produced by sections 17b and- 170' of the frequency changer 17; these sections are controlled by'scctions 25b andj25c of the pulse generator which are similar in all material respects to-section 25a except that the inputs are. provided by I slip frequency signal as indicated in the drawing. 1

"it appears from theoretical considerations and from oscilloscope traces that the operation of the circuits is as illustrated in the-diagrams constituting FIGURES 3, 4, 5A and 5B. The mode of operation that takes place when the slip frequency signal is zerofor a finite period of time is illustrated in FIGURE 3. For this condition the output voltage of the frequency changer should be zero. To obtain zero output voltage with a three phase, half wave circuit as shown with zero slip frequency signal input, the high frequency control signals to the cores must be 90 behind the points of natural commutation P; i.e., 120 behind the high frequency supplyto the corresponding controlled rectifie'rs. This lag is obtained as explained above by the phase connections. to windings'SI arid61 and by the inductances 67,- 68 and 69. In Figure 4, the voltages of high frequency supply phases a; b and c' to the rectifiers 1 and 2-are shownjthe high frequency signal inputs to the windings 51 and 61 are not separately shown, because input phases a, b and c lag one another lay-120 and may be considered as also representing the high frequency signal currents. The signal current a" is equal to zero. Under this condition rectifier 2 of the positive group fires when the high frequency signal current in winding 61 on core 2' passes through zero. The high frequency signal current may be'considered as coinciding with voltage b, and the shaded portion under the curve-a indicates the low frequency output voltage of rectifier'Z.

- Inasmuch as the rectifier is working into an inductive load and, as a practical matter, .into an apparatus having a substantial back E'.M.F., conduction of rectifier 2 continuesuntil rectifier 4 c'ontrollingphase b' is fired. Conduction of rectifier 4 like that of rectifier 2 continues until rectifier 6 controlling phase c is fired. It will be noted that the. areas-above and below the zero line are equal. Hence, there is no'net-voltage and no net cur rent furnished to slip frequency supply phase a, the peaks being smoothed out by the action of the chokes 40 and 42. The conduction of each'rectifier is stopped at the time the next rectifier is fired. This figure assumes that thezrectifiers 1, Sand 5 of the negative group are held non-conducting, the cores '1', 3 and '5' being prevented frorn'fin'ng by current tiowingin the windings 53. It is equallyreasonable to assumethat the rectifiers of the positive group are held non-conductive and the negative rec'tifiers are fired, or that, because of the natureof the load, no substantial current flows during the portions ofin which case the rectifiers of 'the the rectifiers of the negative group quency supply phase a. In anyevent, no current is trans- 8 the positive half cycles that the rectifiers are conductive, positive group and would fire alternately. Also, if the load were purely resistive and the power factor 100%, then the re'ctifiers in the negative group would be fired alternately with the rectifiers in the positive group, again resulting in zero output to the slip fremitted to the slip frequency supply phase a. The same action takes place in the other sections of the frequency changer 17 and the pulse generator 25, so that no voltage is supplied to the rotor windingsof the main generator.

I FIGURE 4 shows the operation when the slip he signal is a negative direct voltage for a finite negative voltage advances the firingof the cores 2, 4 and 6 to a point about 60 after the beginning of eachpositive half cycle, the periods of-conduction of the positive rectifiers 2, 4 and 6 being indicated by the shaded areas as before. The resultant direct voltage is indi catcd by the solid black line a parallel to the zero, axis.

' In this mode of operation the peaks and valleys are again smoothed out by the chokes; the negative cores 1', 3' and 5' are prevented from firing by the current flowing through windings 53. It will be evident that by increasing or decreasing'the value of the D.C.-signal a" that the output voltage of phase a can be correspondingly varied. It will also be evident that by applying a signal ofopposite sign' tothe cores through the windings 50 and 60 that the rectifiers in the negative group can be caused to fire through the firing of the cores 1',

" and 5'. The time of firing of the cores can be advan 'ed as far as the points of-natural commutation P, which will provide maximum output. Thus, if the 'voltage of the slip frequency signal is slowly varied from negative through'zer'o to positive in acyclic manner at the output voltage will vary in a correspondingmanner. Each section of the frequency changer 25 produces one phase of the desired output in accordance with the signal of one phase of the slip frequency signal.

Inasmuch as the rectifiers are arranged back to back and sincethere is no direct current link in the static frequency changer, the changer is able to in either direction and at any power factor. The frequency changer can function even though the instantaneous values of the low frequency current and low frequency voltage are of opposite sign. FlGURi-LS 5A and 5B illustrate the operation of the device at a frequency ratio' of three to one and a power factor of about 0.7. The high frequency input phases are indicated by a, b and c as before; the slip frequency signal is shown by the dotted line a" While the slip frequency output voltage of phase a is shown by the solid line. This line is smoothed by the chokes 40 and 42. The output of the rectifiers, withoutsmoothing, wouldbc a jagged wave jagged wave is not shown in the drawing in order to avoid confusion in illustration. The resulting lagging current output is shown at i,, in FIGURE 58. frequency changer is-operating in a mixed rectification and inversion mode in these diagrams." During approximately the first one-eighth of the cycle of output voltage a, the frequency changer operates in inversion because the instantaneous values of the low' frequency current and low frequency voltage are of opposite sign. Rectification takes place during the balance of the positive half'cycle because the instantaneous current and voltage have the stune sign. The positive grou of controlled rcctifiers operate for the positive half cycle of the current but not necessarily for the positive half cycle of the voltage. Only for a purely resistive load would the-positive rectificrsbe operating during the entire positive half cycle of the voltage. The windings 53. and 63 which saturate the cores when current is flowing through the negative and positive rectifiers, re-

of time as indicatedby the dotted line a". This transmit power 9 spectively, determine which group of rectifiers will operate and prevent firing of the cores of one group when the rectifiers' associated with the cores of the other group are conducting current.

Because the controlled rectifiers turn on almost instantaneously but require a small amount of time to shut off because of the inductance of the synchronous exciter output windings, the windings 52 and 62 are employed to slightly advance the firing points of the cores and thereby to compensate for commutating overlap, and to compensate for the lag in firing that takes place because of the magneticcharacteristics of the core material. The additional ampere turns furnished by these coils have the effect of slightly shifting zero axis which shifts the firing point of the cores that are associated with the -controlled rectificrs that are conducting. When the positive group 2, 4 and 6 of controlled rectifiers are conducting, the current passed by thsm develops a voltage across the shunts 7l, supplying additional ampere turns to the cores controlling the positive groups.

Similarly. when the negative rectifiers 1, 3 and are conducting, the voltages developed across the shunts 70 supply a current to the windings 52 that shift the firing points of the cores 1', 3 and 5'. Those skilled in the art will appreciate that circuits other than the shunt arrangements shown could be employed for providing the current to these windings. Also, the windings 53 and 63 could be fed from the shunts instead of passing the entire current through the windings.

The diagrams constituting FIGURES SA and 5B are given only by way of example; similar diagrams for other modes of operation can be constructed by those skilled in the art, the firing points of the magnetic cores being determined by graphic or algebraic addition of the ampere turns supplied to the cores by the several input windings. Similar determinations of output voltage and current wave forms can be made by phasor analysis.

An analysisof the frequency changer and pulse generator by these methods shows that the frequency changer is capable of transferring power in either direction between the high frequency supply and the slip frequenc supply and is capable of transmitting both reactive and real power. This also has been demonstrated by tests. Another advantage of this type of static frequency changer is that it is a single conversion device, and, hence, has inherently extremely high efiiciency. Because of the high efficiency, dissipation of heat is not a serious problem. The components are sturdy and long-lived; and by multiplying the numbers of controlled rectifiers and magne'tic Cores employed, the load can be divided among the controlled rectifiers so that any reasonable amount of excitation current can be handled with the transmission of power in either direction.

A modified, and in some respects preferred, system em-.

bodying the present invention is illustrated in FIGURES 6 and 7 of the drawings. In this system the'main generator 11 is an induction machine similar in all material respects to the generator 11 previously described and having exciting windings 12' and output windings 14' that supply the buses A synchronous condenser 15' may be connected to the output buses as before. As in the previous modification, the exciting windings 12' of the main generator rotor are supplied through slip rings with slip frequency excitation current having phases a. 1 and c, by means of a static frequency changer 17'. The requirements and characteristics-of the excitation current arethe same as described in connection with the previous modification. The shaft S carries, in addition to the main generator, an exciter generator 18. This is a synchronous machine; but this machine has the same number of poles as the main generator; its high frequency output, therefore, is at shaft frequency. Exciter 18 may be excited by a permanent magnet generator 22', through an appropriate rectifier and control 23', as in the previous modification. In this modification of the invention, there is no slip'frequency generator. Instead, the proper signals for the frequency changer 17' are derived in the pulse generator 25' from the shaft frequency and from a three phase constant reference frequency signal having a frequency equal to the desired output frequency of the main generator. The reference frequency phases are indicated at a", b" and c". The required constant reference frequency may be produced by any convenient source 28'.

The frequency changer 17' is similar in all material respects to the frequency changer 17 previously described, and in FIGURE 7 the same reference characters have been applied to the frequency changer 17' as used for corresponding components in the frequency changer 17. The pulse geenrator 25' is also. essentially the same as the pulse generator 25 previously described insofar as the magnetic cores and the windings thereon are concerned, and the same reference characters usd in FIGURE 2 have been used in FIGURE7 on the corresponding components of pulse generator 25'. It is to be noted, however, thatin this form of the invention the windings 50 and 60 on cores 1' and 2' in section 25a of the pulse generator are supplied by phase a" of the reference frequency source; windings 50 and 60 of cores 3 and 4' are supplied by phase b"; and windings 50 and 60 on cores 5' and 6 are supplied by phase 0'' of the reference frequency source.- In sections 25b and 25c of the pulse generator, the relationship between the phases is changed in order to provide pha'scs b and c of the slip frequency supply. Thus, in sections 2511' and 25c the shaft frequency supply to the several cores, as diagramatically inand 6" are supplied with phase a" of the reference frequency. In section 25c windings 50 and 60 on cores '1 and 2' are supplied by phase c", windings 50 and 60 on cores 3 and 4' are supplied by phase a"; and windings 50 and 60 on cores 5' and 6' are supplied by phase b" or the reference frequency. This provides the proper phase relationship in the slip frequecy supply phases a, b and-c.

Three modes of operation of thesystem shown in FIG- URES 6 and 7 are illustrated diagrammatically in FIGS. 8, 9 and It). In FIGURE 8A, curves 0, b and 0' indicate the high frequency (i.e., shaft frequency) input to the reetifiers 1 and 2, and the shaded portions of the curve indicate the low frequency output voltage, the net effect of which is zero as in FIGURE 3; Zero output is obtained when shaft frequency is precisely in phase with the reference frequency. In FIGURE 8B, curve 1', indicates the reference frequency derived from the constant frequency source and curve i indicates the shaft frequency minus these being the input frequencies to windings 50, 51, 60 and 61 on cores 1 and 2' of pulse generator 25a. Curve f shows the resultant ampere turns on the cores. This curve crosses zero at substantially thesarne time as the flux saturation curve of the cores. Assuming the cores of the positive group to be firing, core 2 will fire and rectifier 2 conduct when curve 1 crosses through zero in the negative to positive direction.- This occurs 60 after the points of natural commutation Rfand as explained in connection with FIG- URE 3, produces the net zero voltage and current output indicated'in FIGURE 8A. Only one phase of the input currents is indicated in FIGURE 88 for convenience of illustration.

FIGURES 9A and 9B illustrate the mode of operation when the apparatus is operating at synchronous speed. but the reference frequency signal is advanced about l20 with respect to the supply voltage. .As shown in FIGURE 9A, this causes the rcctifiers to become conductive after about 60 in each positive half cycle, thus producing the resultant DC. voltage indicated by line a, the shaded areas againindicating the voltage on the output side of the rectifiers.

FIGURE 9B shows one phase ofthe firing circuits. Curve 1', indicates the reference current; curve i indicates the shaft frequency minus 120; and curve I represents the total ampere turns on' the core. As before, the cores fire and the rectifiers are made conductive when curve f passes through zero in the negative to positive direction.

. As in FIGURE 88, only one phase of the currents inthe windings on the core are shown.

FIGURE A illustrates one quarter of a cycle showing the operation at a non-synchronous speed. In this figure, curves a, b and c indicate the shaft frequency inputs as before, while curve a indicates one-quarter cycle of the slip frequency output. The shaded areas under the curves show the output voltages on the rectifiers from which the curve a is synthesized.

-' FIGURE 10B illustrates the firing currents. Again 1', is the constant reference frequency, i is the shaft frequency minus 120, and curve f indicates the total ampere turns on the core. This is for the circuits controlling phase a only of the shaft frequency input to the frequency changer. It will be noted that the-shaft frequency is slightly greater than the reference frequency and that the firing of the cores synthesizes a frequency that is the difference betwen the shaft frequency and reference frequency, this being the slip frequency. Mathematical and phasor analysis, as well-as tests of the apparatus, demonstrate that the frequency changer, when controlled by the'pulse generator of this modification, is able to transrn'itboth real and reactive power in either direction. In this form of the invention, the speed range is somewhat less than-in the prev-iousform, but this form is advantagenus because the slip frequency generator is eliminated.

From the foregoing description of preferred forms of the invention, it will be evident that we have provided a system for generating alternating current of substantially constant frequency regardless of comparatively wide variations in the speed-of the prime mover that drives the machine. The frequency of the output of the system is always identical with the reference frequency and, therefore, the output frequency can be maintained very accurately. With systems made'according to the modifica tion disclosed in FIGURES 1 and 2 of the drawings, speed ratios of maximum to minimum speeds of the drive shaft of 3 to 1 can be handled readily while maintaining the output frequency substantially constant. Even greater speed ratios can be tolerated if the frequency of the synchronous exciter isincreased or the number of poles in the synchronous exciter is increased. With the apparatus shown in the second modification where the synchronous exciter contains the same number of poles as the main alternator, shaft speed ranges of 2 to I can be accommodated readily. Inasmuch as the frequency changer is capable of transmitting both real and reactive power in either direction, efficient operation of themain induction machine can be obtained; at speeds above synchronous speeds the exciter acts as a motor, putting power back into the shaft, thus improving the efficiency of the system as c'ornpared to systems where the power is wasted. The frequency changer is requiredto handle only the excitation currents, and therefore it is not unduly loaded. The frequency changer and pulse generator are made up of small, rugged components having no moving parts, making the system ideally suited for use in aircraft and missiles.

The apparatus can be utilized with conventional controls and protective devices. In the first modification illustrated, the slip frequency generator embodies a commutator; but this is required .to handle no'substantial amounts of power, so commutating problems are not serious. In the second modification, no commutator 'is required. A slip ring main generator is illustrated, but it is evident that brushless machines of various types known in the art could be utilized if desired. For example, the output and exciting windings of the exeiter 18 could. be mounted on the rotor and stator, respectively,

and the pulse generator and the static frequency changer mounted on the shaft, thus eliminating slip rings from the excitcr and the main generator.

Various changes and modifications can be made in the preferred form of the invention disclosedhcrein without departing from the spirit and scope thereof. The essential characteristics of the invention are defined in the appended claims.

We claim:

1. Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a variable speed shaft, a synchronous exciter connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer embodying pairs of current-controlled electronic switching and rectifying devices with the devices-in a pair arranged back to back, and a pulse generator for controlling the firing of said rectifiers to change the frequency of the output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings.

2. Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially below synchronous speed to substantially above synchronous speed, a synchronous condenser connected to the output of said main generator, a synchronous exciter connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer embodying pairs of current-controlled electronic switching and rectifying devices with the devices in a pair arranged back to back, and a pulse generator for controlling the firing of said rectifiers to change the frequency of the output of said synchronou exciter to slip frequency with interchange of both real and reactive power in either direction between 0 said synchronous exciter and said exciting windings.

3. Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having 'a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a variable speed shaft, a constant frequency source, a synchronous exciter connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer embodying pairs of current-controlled electronic switching andrectifying devices with the rectifiers in a pair arranged back to back, and a pulse generator for controlling'the firing of said rectifiers to change the frequency of the output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings, said pulse generator being controlled by currents derived from said synchronous exciter and from'said constant frequency source.

4. Apparatus according to claim 3 wherein the current derived from the constant frequency source is at the frequency of the constant frequency source.

5. Apparatus according to claim 3 wherein a second frequency changer-is provided to derive slip frequency from said constant second frequency source and the out- 7. Apparatus for generating alternating current of sub stantially constant frequency at varying shaft speeds comthe outputof said main generator, a constant frequency source, a synchronous exciter connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer embodying pairs of current-controlled electronic switching and rectifying devices with the rectifiers in a pair arranged back to back, and a pulse generator for controlling the firing of said rectifiers to change the frequency of'the output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous excit'er and said exciting windings, said pulse generator comprising a saturable core transformer for each of said electronic switching and rectifying devices, said transformers being controlled by currents derivedfrom said synchronous exciter and from said constant: frequency source to produce-firing pulses for said electronic switching and rectifying devices.

8; Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having astator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven-by a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially-below synchronous speed to substantially above synchronous speed, a synchronous exciter connected to said shaft, a static frequency changer connected between said changer comprising a plurality of pairs of controlled rectifiers for eachphase' of said exciter with the rectifiers in a pair arranged back to back, and a pulse generator controlled by a current derived from the output of said exciter and a current derivedfrom a constant reference freqency for controlling the firing of said rectifiers to change the output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings.

9. Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and theother having output windings, said rotor being driven by a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially below synchronous speed to substantailly above synchronous speed, a synchronous exciter having the same number of poles as said main generator connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer comprising a plurality of pairs of controlledrectifiers, there being one pair for each phase of said exciter with the rectifiers in a pair arranged back to back, and a. pulse generator controlled by a current derived from the output of said exciter and a constant frequency current having the desired output frequency for controlling the firing of said rectifiers to change the output ,of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings.

'10. Apparatus substantially constant for generating alternating current of frequency at varying shaft speeds comprising a main induction generator having a stator and said elements having polyphase exciting a rotor, one of having output windings, said rotor windings and the other being driven by a shaft, said shaft being adapted to be driven throughout a speed range extending substantially below synchronous speed to substantially above synehronous speed. a synchronous exciter having a greater number of poles than said main generator connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer comprising a plurality of sections, one for each phase of said exciting windings, each section embodying a pair of current-controlled electronic switching and rectifying devices,'there being one pair for each phase of said exciter with the devices in a pair arranged back to back, and a pulse generator controlled by a current derived from theoutput of said exciter and a current derived from a constant reference frequency for controlling the firing of said electronic switching and rectifying devices to change the high frequency output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings.

11. Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a variable speed shaft, a synchronous exciter connected to said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer comprising a plurality of sections, one for each phase of said exciting windings, each section embodying a pair of current-controlled electronic switching and rectifying devices for each phase of said exciter-with the devices in a pair arranged back to back, and a pulse generator comprising a saturable core transformer for each of said electronic switching and rectifying devices, each such transformer being controlled by a current derived from the output of said exciter and a current derived from a constant reference frequency for controlling the firing of said electronic switching and rectifying devices to change the high frequency output of said synchronous ex-v citer to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings. V

12. In an apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven bya variable speed shaft, and a synchronous exciter connected to saidshaft, the improvement comprising a static frequency changer connected between said synchronous exciter and said exciting windings for supplying slip frequency excitation to said exciting windings, said frequency changer comprising a plurality of sections, one for each phase of said exciting windings, each section embodying a pair of controlled rectifiers for each phase of said exciter with the rectifiers in each pair arranged back to back, all of the rectifiers that conduct in one direction in section' being connected together in a group on the slip frequency side of the frequency changerand all of the rectifiers that conduct in the opposite direction being connccted together in another group, said groups of rectifiers being connected to the ends of a center-tapped choke on the slip frequency side of the frequency changer and the center tap of the choke being connected to one of the phases of the exciting windings,- and a pulse generator controlled by a current derived from the output of said exciter and a current derived from a constant reference frequency for controlling the firing of said rectifiers to change the high frequency output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings.

stantially below synchronous speed to substantially above synchronous speed, and a synchronous exciter connected to said shaft, the improvement comprising a static frequency changer connected between said synchronous ex- I citer and said exciting windings for supplying slip frequency excitation to. said exciting windings, said frequency changer comprising a plurality of sections, one for each phase of said exciting windings, each section embodying a, pair of controlled rectifiers for each'phase of said exciter with the rectifiers in each pair arranged back to back, all'of the rectifiers that conduct in one direction in sectionbeing connected together in a group on the slip frequency side of the frequency changer and all of the rectifiers that conduct in the opposite direction being connected together in another group, said groups of rectifiers being connected to the ends of a'center-tapped choke on,

the slip frequency side of the frequency changer and the center tap of the choke being connected to one of the phases of the'exciting windings, and a pulse generator controlled by a current derived from the.- output of said exciter and a currentderived from a constant reference frequency forcontrolling the firing of said rectifiers to change the high frequency output of'said synchronous-exciter to slip frequency with interchange of both real and reactive power in :eitherdirection between said synchronous exciter'and said exciting windings, said pulse generator comprising a saturable core transformer for each controlled rectifier in the static frequency changer, each transformer having an input winding carrying a-current derived from the output of said synchronous exciter and an input winding carrying a current derived from a constantfrequency source,-and an output winding for supplying a firing pulse to one of said rectifiers.

v 14. In an apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator'having a stator and a rotor, one -'of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially below synchronous speed to substantially above synchronous speed, and a synchronous exciter driven by said shaft, the improvement comprising a static frequency changer Connected between said synchronous exciter and said exciting windings, said frequency changer embodying pairs of current controlled electronic switching and rectifying devices with the switching devices in a pair arranged back to back, and a pulse generator for controlling the firing of said switching devices to change the frequency of the output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings, said pulse generator comprising a saturable core transformer for each switching device inthe static frequency changer, each transformer having an input winding carrying a current derived from the output of said synchronous exciter and an input winding carrying a current derived from a constant' frequency source. and an output winding for supplying afiring pulse to one of said switching devices.

15. In an apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, onc of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a variable speed shaft, and'a synchronous exciter driven by said shaft, the improvement comprising astatic frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer embodying a plurality of current controlled electronic switching and rectifying devices, and a pulse generator for controlling the firing of said switching devices to change the frequency of the output of said synchronous exciter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings, said pulse generator comprising a saturable core transformer for each switching device in the static frequency changer, each transformer having an input winding carrying a current derived from the output of said synchronous exciter and an input winding carrying a current derived from a constant frequency source, and an output winding for supplying a firing pulse to one of said switching devices.

16. Apparatus for generating alternating current of substantialy constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by .a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially belowsynchronous speed to substantially above synchronous speed, a synchronous exciter driven by said shaft, a static frequency changer connected between said synchronous'exciter and said exciting windings, said frequency changer embodying pairs of current controlledelectronic switching and rectifying devices with the switching devices in a pair back to back, and a pulse generator for controllingthe firing of said switching devices to change the frequency of the output of said synchronous exciter to slipfrequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings, said pulse generator comprising a plurality of saturable core transformers, one for each switching device in the static frequency changer, each transformer having an input winding carrying a current derived from the output of said synchronous exciter, an input winding carrying a current derived frorn' a constant frequency source, an input winding carrying a current derived from the output of a switching device that conducts oppositely from the switching device that is controlled by the particular transformer, and an output winding for supplying a firing pulse to one of the controlled rectifiers.

17. Apparatus for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially below synchronous speed to substantially above synchronous speed, a synchronous exciter driven by said shaft, a static frequency changer connected between said synchronous exciter and said exciting windings, said frequency changer embodying pairs of current controlled electronic switching and rectifying devices with the switching devices in a pair arranged back to back," and a pulse generator for controlling the firing of said switching devices to 'change the frequency of the output of said synchronous exciter to slip frequency with interchange -of both real and reactive power in either direction between said synchronous exciter and said exciting windings, said pulse generator comprising a plurality of saturable core transformers, one for each switching device in the static frequency changer, each transformer having an input winding carrying a current derivedfrom the output of said synchronous exciter, an input winding carrying a current derived from a constant frequency source, an input winding carrying a current derived from the output of a switching device that conducts oppositely from the switching device that is controlled by the particular transformer, a compensating input winding for advancing the firing of the transformer,

V stator and a rotor, one of said one of the controlled rectifiers.

18, In an apparatus for generating alternating current of substantially constant frequency 'at varying shaft speeds comprising a main induction generator having a elements having polyphase exciting windings and the other having output windings, said rotor being driven by a shaft, said shaft being adapted to be driven throughout a speed range extending from substantially below synchronous speed to substantially ,above synchronous speed, and a synchronous exciter driven by said shaft and having the same number of poles as said main generator, the improvement comprising a static frequency changer connected between said synchronous exciter and said exciting windings, said frequencychanger embodying pairs of current controlled electronic switching and rectifying devices with the switching devices in a pair arranged back to back, and a l pulse generator for controlling the firing of said switching devices to change the frequency of the output of said synchronous exeiter to slip frequency with interchange of both real and reactive power in either direction between said synchronous exciter and said exciting windings, said pulse generator comprising a plurality of saturable core transformers, one of each switching deviceiin the static frequency changer, each transformer having an input winding carrying a shaft frequency current derived from the output-of said synchronous exciter, an' input winding carryinga current having frequency equal to the desired output frequency, and an output winding for supplying a firing pulse to one of the controlled rectifiers.-

19.= In an apparatus'for generating alternating current of substantially constant frequency at varying shaft speeds comprising a main induction generator having a stator and'a rotor, one of said elements having polyphase exciting windings and the other having output windings, said rotor being driven by a shaft, said shaft being adaptedto'be driven throughout a-speed range extending from substantially below synchronous speed to substantially above synchronous speed, and a synchronous exciter driven by said shaft and having the same number of poles as saidma'in generator, the improvement comprising a static frequency changer connected between said synchronous excitcr and said exciting windings, said frequency-changer embodying pairs of controlled rectifiers .with the rectifiers in a pair arranged back to back, and a pulse generator for controlling the firing of said rectifiers to change the frequency of the output of said synchronous exciter to slip frequency with interchange of both real and active power in either 'direction between said synchronous excitcr and said exciting windings, said pulse generator comprising a plurality of saturable core transformers, one for each rectifier in the static frequency changer, each transformer having an input winding carrying a shaft frequency current derived from the output of said synchronous exciter, an input winding carrying a current having frequency equal to the desired output frequency, an input-winding for preventing the firing of the transformer while the other rectifier in the pair to one of which the transformer is connected is conducting,-and an output winding forsupplying a firing pulse to one of the t the controlled rectifiers.

20. A static frequency changer comprising pairs of current controlled electronic switching and rectifying devices with the switching devices in a pair arranged back to back, and a pulse generator for controlling the firing of said switching devices to change the frequency of the input to said frequency changer to a desired output frequency with interchange of both real and reactive power in either direction, said pulse generator comprising a saturable core transformer for each switching device in the static frequency changer, each transformer havingan input winding for controlling the firing of the transformer and an output for supplying a firing pulseto'oneof said switching devices.

21. A static frequency changer comprising pairs of current controlled solid state electronic switching and rectifying devices with the switching devices in a pair arranged back to back, and a pulse generator for controlling the firing of said switching devices to change the frequency of the input to said frequency changer to a frequency that is equal to the dificrencc between two frequencies with interchange of both real and reactive power in either direction, said pulse generator comprising a plura'ty of saturable core transformers, one for each switching device in the static frequency changer, each transformer having an input winding carrying a current of one of said two frequencies, an input winding carrying a current of the other of said two frequencies, and an output winding for supplying a firing pulse to one of the controlled rectifiers.

22. A static frequency changer comprising pairs of current controlled solid state electronic switching and rectifying devices with the switching devices in a pair arranged back to back, and a pulse generator for controlling the firing of said switching devices to change the frequency of the input to said frequency changer to a frequency that is equal to the difference between two frequencies with interchange of both real and reactive power in either direction, said pulse generator comprising'a plurality of saturable core transformers, one for each switching device in the static frequency changer, each transformer having an input winding carrying a current of one of said two frequencies, an input winding carrying a current of the other of said two frequencies, an input winding carrying a current derived from the output of a switching device that conducts opposite- 1y from the switching device that is controlled by the particular transformer, and an output winding for supplying a firing pulse to one of the controlled rectifiers. 23. A stati frequency changer comprising pairs of current controlled solid state electronic switching and rectifying devices with the switching devices in a pair arranged back to back, and a pulse generator for controlling the firing of said switching devices to change the frequency of the input to said frequency changer to a frequency that is equal tov the difference between two frequencies with interchange of both real and reactive power in either direction, said pulse generator comprising a plurality of saturable core transformers, one for each switching device in the static frequency changer, each transformer having an input winding carrying a current of one of said two frequencies, an input winding carrying a current of the other of said two frequencies, an input winding carrying a current derived from the output of a switching device that conducts oppositely from the switching device that is controlled by the particular transformer, a compensating input winding for advancing the firing of the transformer, and an output winding for supplying a firing pulse to one of the controlled rectifiers.

24. A static frequency changer connected between a polyphase input and a polyphase output, said frequency changer comprising a plurality of sections, one for each phase of said output, each section embodying a pair of controlled rectifiers for each phase of said input with the rectifiers in each pair arranged back to back, all of the rectifiers that conduct in one direction in a section being connected together in a group on output side of the frequency changer and all of the rectifiers that conduct in the opposite direction being connected together in another group, and a pulse generator for controlling the firing of said rectifiers to change the input frequency to a desired output frequency with interchange of both real and reactive power in either direction between said input and said output, said pulse generator comprising a saturable core transformer for each switching device in the static frequency changer, each trans former having an input winding, and an output winding for supplying a firing pulse to one of said rectifiers.

2,995,696 19 20 25. A static frequency changer connected between a real and reactive power in either direction between said polyphase input and a polyphasc output, said frequency input and said output, said pulse generator comprising changer comprising a plurality of setcions, one for each a saturable core transformer for each switching device phase of said output, each section embodying a pair of in the static frequency changer, each transformer havcontrolled rectifiers for each phase of said' input with 5 ing an input winding carrying a current derived from the rectifiers in each pair arranged back to back, all of said input and an input winding carrying a current the rectifiers that conduct in one direction in a section derived from a constant frequency source, and an output being connected together in a group on output side of winding for supplying a firing pulse to one of said the frequency changer and all of the rectifiers that conreetifiers.

duct'in the opposite direction being connected together 10 in another group, said groups of rectifiers being con- References Cited in the file of this patent nected to the tittllads of a c'enteztapped chotlrficon the UNITED STATES PATENTS output side of e frequency c anger and center tap of the choke being connected to one of the phases f g a 2 of said output, and a pulse generator for controlling 15 2'831156 9 the firing of said rectifiers to change the input frequency Mat ews et 1958 to a desired output frequency with interchange of both 2'854617 Johnson Sept 1958 4, UNITED STATES PATENT OFFICE ER IFICATE OF CORRECTION Patent No; 2,995,696 August 8, 1961 Lawrence J. Str-atton et al.

It is hereby certified that error appears in the above numbered pat- 'ent requiring correction and that the said Letters Patent should read as corrected below.

Column 2, line 40, for "The" read These column 6,

line 19,. before "winding" strike out "the"; column 10, line 13, for "geenrator read generator line 33, for "6" read c in italics; column 12, line 70, strike out lisecond"; line 71, before "frequency" insert second Column 17, line 25, for "of" read for line 49, for

"active" read reactive Signed and sealed this 6th day of February 1962.

(SEAL) Attest:

ERNEST W. SWIDER DAVID L. LADD Atteeting Officer Commissioner of Patents

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